Variable spoiler apparatus of rear bumper for vehicle

ABSTRACT

Disclosed is a variable spoiler apparatus of the rear bumper for vehicles. The variable spoiler apparatus includes a linkage device, to be installed on a bumper back beam, which is able to vary in length in an up-down direction during a rotating operation. A spoiler is coupled to the linkage device and is able to move in the up-down direction by the rotation operation of the linkage device. A first drive device, to be installed on the bumper back beam, includes a first rotating shaft coupled to the linkage device to transmit a rotating force. When the first drive device is operated, the linkage device is rotated by a rotation of the first rotating shaft so that the spoiler is moved in the up-down direction. A second rotating shaft is rotatably coupled to the linkage device. The second rotating shaft is penetrated and connected to a second drive device.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority of Korean Patent Application No. 10-2016-0151736 filed on Nov. 15, 2016, the entire contents of which is incorporated herein for all purposes by this reference.

TECHNICAL FIELD

The present invention relates to a variable spoiler apparatus of a rear bumper for vehicles.

BACKGROUND

Generally, when vehicles travel at high speeds or turn, the grip force of rear wheel tires is reduced. The reduction in grip force is disadvantageous for the vehicle to increase the speed, and causes deterioration in the driving stability of the vehicle.

To overcome the above-mentioned problems, an air spoiler is installed in the rear of the vehicle. The air spoiler changes the flow of air passing around a vehicle so that the pressure of pushing the vehicle can be generated by the flow of air around the air spoiler, thus increasing the grip force of the rear wheel tires.

Such an air spoiler is typically installed on the rear end of a vehicle. In this regard, the degree of freedom in design is limited. Once the air spoiler has been installed, it is difficult to change the design. In the case where the air spoiler is applied to a high-quality vehicle, there is a problem in that the design quality may deteriorate due to the installation of the air spoiler.

As such, the air spoiler is limited as a technique for improving the aerodynamic performance to enhance the fuel efficiency and driving stability of the vehicle. There is a problem in that the shape of the vehicle or the specifications of the air spoiler must be changed to additionally improve the aerodynamic performance.

The foregoing is intended merely to aid in the understanding of the background of the present invention, and is not intended to mean that the present invention falls within the purview of the related art that is already known to those skilled in the art.

SUMMARY

Accordingly, the present invention has been made keeping in mind the above problems occurring in the related art, and the present invention is intended to propose a variable spoiler apparatus of a rear bumper for a vehicle which is housed in the lower portion of the rear bumper and, as needed, is extracted downward from the rear bumper so as to control the air flow, thus making it possible to enhance the driving stability and aerodynamic performance of the vehicle.

According to one aspect, there is provided a variable spoiler apparatus of a rear bumper for a vehicle, including: a linkage device installed on a bumper back beam and configured to vary in length in an up-down direction during a rotating operation; a spoiler coupled to the linkage device and configured to be moved in the up-down direction by rotation of the linkage device; a first drive device installed on the bumper back beam and provided with a first rotating shaft coupled to the linkage device to transmit rotating force, the first drive device being configured such that, when the first drive device is operated, the linkage device is rotated by rotation of the first rotating shaft so that the spoiler is moved in the up-down direction; a second rotating shaft rotatably coupled to the linkage device so that, when the linkage is rotated, the second rotating shaft is moved in the up-down direction along with the rotation of the linkage device; and a second drive device, to which the second rotating shaft is penetrated and connected so that, when the linkage device is rotated, the second drive device is moved in the up-down direction, the second drive device being provided with a length-variable unit coupled to an end of the spoiler so that, when the second drive device is operated, the spoiler is tilted by a length variation operation of the length-variable unit.

The linkage device may include: a fixing bracket fixed to the bumper back beam, and to which the first rotating shaft is penetrated and connected; a drive link including a first end that is installed on the fixing bracket and coupled with the first rotating shaft so that the drive link rotates along with the first rotating shaft; a support link including a first end rotatably coupled to the fixing bracket through a connection link, and a second end rotatably coupled to the spoiler; and a driven link including a first end rotatably coupled to the drive link, and a second end rotatably coupled to the second link of the support link.

The drive link and the driven link may be configured such that, when the spoiler is completely moved downward, the drive link and the driven link that have been in a folded state are unfolded to have an approximately vertical orientation.

The driven link may extend from the first end thereof to the second end in a curved shape.

The connection link may be rotatably coupled at a first end thereof to the fixing bracket, and be rotatably coupled at a second end thereof to the first end of the support link, and the connection link may comprise a plurality of connection links provided parallel with each other.

The linkage device may be configured such that the drive link, the driven link, the connection link and the support link are unfolded to form a triangular shape when the spoiler is completely moved downward.

The first drive device may include: a first motor installed on a back beam bracket fixed on the bumper back beam and configured to transmit rotating force; and a first rotating shaft extending in opposite directions from the first motor, and penetrated into the fixing bracket and connected to the drive link.

The second rotating shaft may be rotatably coupled to the first end of the support link. The second drive device may be provided with an up-down movable member to which the second rotating shaft is penetrated and rotatably coupled, the up-down movable member being coupled with the length-variable unit coupled to the spoiler.

The length-variable unit may include: a rotating bracket rotatably installed on the end of the spoiler; a second motor installed on the up-down movable member and configured to transmit rotating force; and a connection shaft extending from the second motor and threadedly coupled to the rotating bracket so that, when the second motor is operated, the rotating bracket is moved in the up-down direction by rotation of the connection shaft.

The bumper back beam may be installed in a rear of the vehicle. When the spoiler is moved downward, the spoiler may be extracted forward in a diagonal direction.

The length-variable unit of the first drive device may be coupled to a front end of the spoiler.

In a variable spoiler apparatus of a rear bumper for vehicles according to the present invention, a spoiler is housed in a lower portion of the rear bumper and, as needed, is extracted downward from the rear bumper so as to control the air flow, thus making it possible to enhance the driving stability and aerodynamic performance of the vehicle.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description when taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a perspective view illustrating a variable spoiler apparatus of a rear bumper for a vehicle according to an embodiment of the present invention;

FIGS. 2 and 3 are perspective views illustrating the operation of the variable spoiler apparatus of the rear bumper for vehicles shown in FIG. 1; and

FIGS. 4 to 6 are side views illustrating the operation of the variable spoiler apparatus of the rear bumper for vehicles shown in FIG. 1.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The present invention relates to a variable spoiler apparatus of a rear bumper for vehicles which is moved downward or upward under a rear bumper so as to control the air current.

Hereinafter, a variable spoiler apparatus of a rear bumper for vehicles according to embodiments of the present invention will be described with reference to the attached drawings.

FIG. 1 is a perspective view illustrating a variable spoiler apparatus of a rear bumper for a vehicle according to an embodiment of the present invention. FIGS. 2 and 3 are perspective views illustrating the operation of the variable spoiler apparatus of the rear bumper for vehicles shown in FIG. 1. FIGS. 4 to 6 are side views illustrating the operation of the variable spoiler apparatus of the rear bumper for vehicles shown in FIG. 1.

As shown in FIG. 1, the variable spoiler apparatus of the rear bumper for vehicles according to an embodiment of the present invention includes: a linkage device loo which is installed on a bumper back beam 10 and configured to vary in length in an up-down direction during a rotating operation; a spoiler 200 which is coupled to the linkage device 100 and configured to be moved upward or downward by the rotation of the linkage device 100; a first drive device 300 which is installed on the bumper back beam 10 and provided with a first rotating shaft 340 coupled to the linkage device loo to transmit rotating force, and which is configured such that, when the first drive device 300 is operated, the linkage device 100 is rotated by the rotation of the first rotating shaft 340 so that the spoiler 200 is moved upward or downward; a second rotating shaft 400 which is rotatably coupled to the linkage device 100 so that when the linkage device 100 is rotated, the second rotating shaft 400 is moved in the up-down direction along with the rotation of the linkage device 100; and a second drive device 500 to which the second rotating shaft 400 is penetrated and connected so that, when the linkage device 100 is rotated, the second drive device 500 is moved in the up-down direction, and which is provided with a length-variable unit 520 connected to an end of the spoiler 200 so that, when the second drive device 500 is operated, the spoiler 200 is tilted by a length variation operation of the length-variable unit 520.

As such, embodiments of the present invention are formed of the linkage device 100, the spoiler 200, the first drive device 300, the second rotating shaft 400, and the second drive device 500. The linkage device 100 may be provided to have a symmetrical structure on opposite sides of the spoiler 200. The linkage device 100 is fixed to the bumper back beam 10. The bumper back beam 10 may be a bumper back beam 10 that is provided on a rear bumper. The linkage device wo may be formed of a plurality of links and configured such that, when the links are rotated and thus folded or unfolded, the length of the linkage device 100 varies in the up-down direction.

The spoiler 200 is connected to the linkage device 100 so that the spoiler 200 moves upward or downward as the length of the linkage device 100 varies in the up-down direction. In an original state, the spoiler 200 is housed in a bumper cover 20 provided on the bumper back beam 10. When the spoiler 200 is moved downward from the bumper cover 20 and disposed below the bumper cover 20, the spoiler 200 can be used to control the air flow. The spoiler 200 may be formed in a shape capable of appropriately controlling the air flow when the spoiler 200 is in an exposed state below the rear bumper. The shape of the spoiler 200 may change in various ways depending on the types of vehicles.

In accordance with an embodiment of the present invention, the first drive device 300 is provided. The first drive device 300 controls the rotation of the linkage device 100 so as to embody the upward or downward movement of the spoiler 200. In detail, the first drive device 300 is installed on the bumper back beam 10 and provided with the first rotating shaft 340 that is coupled to the linkage device 100 to transmit rotating force. When the first drive device 300 is operated, the linkage device 100 is rotated by the rotation of the first rotating shaft 340 so that the spoiler 200 is moved upward or downward. As such, the first drive device 300 transmits rotating force to the linkage device 100 through the first rotating shaft 340. That is, depending on whether the first drive device 300 is in operation, the linkage device 100 is rotated so that the spoiler 200 is moved upward or downward and thus retracted into the bumper cover 20 or extracted therefrom.

Particularly, to embody the function of controlling the air flow, the spoiler 200 according to embodiments of the present invention may not only be moved upward or downward but may also be tilted.

For this, the second drive device 500 is coupled to the second rotating shaft 400 connected to the linkage device 100 so that, when the linkage device 100 is rotated by the operation of the first drive device 300, the second drive device 500 is moved upward or downward along with the second rotating shaft 400. Furthermore, the second drive device 500 is connected to the spoiler 200 through the length-variable unit 520 so that when the second drive device 500 is operated, the spoiler 200 can be tilted. That is, the second drive device 500, the length-variable unit 520 of which is connected to the spoiler 200, is coupled to the linkage device 100, so that the second drive device 500 moves following the rotating operation of the linkage device 100. Therefore, when the spoiler 200 is moved upward or downward by the operation of the first drive device 300, the second drive device 500 is moved upward or downward along with the spoiler 200. For example, after the second drive device 500 along with the spoiler 200 has been moved downward, when the length-variable unit 520 coupled to the end of the spoiler 200 is operated, the spoiler 200 can be tilted by variation in length of the length-variable unit 520. As such, when the spoiler 200 is moved upward or downward by the rotation of the linkage device 100 as the first rotating shaft 340 is rotated by the operation of the first drive device 300, the second drive device 500 is moved along with the spoiler 200 in the same direction. Because the length-variable unit 520 is connected to the end of the spoiler 200, the end of the spoiler 200 can be pulled or pushed upward or downward by variation in length of the length-variable unit 520. In this way, the spoiler 200 can be tilted.

As such, the spoiler 200 according to embodiments of the present invention is moved upward or downward and housed into the rear bumper or extracted therefrom depending on the operation of the first drive device 300. When in the extracted state, the spoiler 200 is tilted by the operation of the second drive device 500 so as to control the air current.

The present invention will be described in more detail below. As shown in FIGS. 1 to 3, the linkage device 100 includes: a fixing bracket 110 which is fixed to the bumper back beam 10, and to which the first rotating shaft 340 is penetrated and connected; a drive link 130 a first end of which is installed on the fixing bracket 110 and connected to the first rotating shaft 340 so that the drive link 130 can be rotated along with the first rotating shaft 340; a support link 170 a first end of which is rotatably connected to the fixing bracket 110 through a connection link 150, and a second end of which is rotatably connected to the spoiler 200; and a driven link 190 a first end of which is rotatably connected to the drive link 130, and a second end of which is rotatably connected to the second end of the support link 170.

The linkage device 100 having the above-mentioned configuration forms a link structure formed of the drive link 130, the connection link 150, the support link 170 and the driven link 190 which connect the fixing bracket 110 with the spoiler 200. That is, the first rotating shaft 340 extending from the first motor 320 is penetrated and connected to the fixing bracket 110. The first end of the drive link 130 is rotatably connected to the fixing bracket 110 such that the drive link 130 is rotated along with the first rotating shaft 340. Thus, when the first motor 320 is operated, the first rotating shaft 340 is rotated, whereby the drive link 130 is rotated. The first end of the driven link 190 is connected to a second end of the drive link 130. The second end of the driven link 190 is rotatably connected to the second end of the support link 170. The second end of the support link 170 is hinged to the spoiler 200 so as to be rotatable. Thus, when the first motor 320 is operated, the spoiler 200 can be moved by rotation of the drive link 130, the driven link 190 and the support link 170. In this regard, the spoiler 200 must be moved upward or downward with respect to the bumper back beam 10. For this, the connection link 150 is rotatably connected to the fixing bracket 110 and the first end of the support link 170. Thereby, when the first motor 320 is operated, the drive link 130 and the driven link 190 are rotated, thus pushing the support link 170, wherein the support link 170 is guided in the up-down direction by the connection link 150 connected to the fixing bracket 110 and the support link 170.

Consequently, the spoiler 200 can be moved in the up-down direction by the drive link 130, the driven link 190, the support link 170 and the connection link 150 that constitute the linkage device 100. All of the links constituting the linkage device 100 are hinged to each other so as to be rotatable relative to each other.

As shown in FIGS. 3 and 5, the drive link 130 and the driven link 190 may be configured such that, when the spoiler 200 is completely moved downward from the folded stated, the drive link 130 and the driven link 190 are unfolded to have an approximately vertical orientation.

As such, when the spoiler 200 is completely moved downward, the drive link 130 and the driven link 190 are unfolded to an angle close to the vertical orientation. Thus, the drive link 130 and the driven link 190 are maintained at an angle close to an angle perpendicular to the spoiler 200 so that the support force of the drive link 130 and the driven link 190 can be reliably secured while the spoiler 200 is in the downwardly moved state.

Particularly, since the driven link 190 extends from the first end thereof to the second end in a curved shape, the driven link 190 can be smoothly rotated when the drive link 130 rotates. In detail, as shown in FIGS. 2 and 5, the driven link 190 extends to be curved in the direction in which the drive link 130 rotates. Thus, when the drive link 130 rotates to move the spoiler 200 downward, the driven link 190 can easily receive the rotating force in the direction in which the drive link 130 rotates, whereby the driven link 190 can smoothly rotate in a predetermined direction following the direction in which the drive link 130 rotates.

The connection link 150 is rotatably connected at a first end thereof to the fixing bracket 110, and is rotatably connected at a second end thereof to the first end of the support link 170. A plurality of connection links 150 may be provided to be parallel with each other. The first end of the connection link 150 is hinged to the fixing bracket 110 so as to be rotatable, and the second end thereof is hinged to the first end of the support link 170 so as to be rotatable. Thus, when the first motor 320 is operated, the connection link 150 makes the drive link 130, the driven link 190 and the support link 170 rotate in predetermined directions with respect to the up-down direction. Particularly, the connection link 150 is connected to the fixing bracket 110 and the support link 170 and thus supports the spoiler 200 connected to the support link 170. Given this, it is preferable that the connection link 150 have the strength sufficient to overcome the force caused by vehicle-induced wind applied to the spoiler 200. For this, a plurality of connection links 150 may be provided so that the spoiler 200 can be reliably maintained in the correct position even when vehicle-induced wind is applied to the spoiler 200 while the vehicle travels. The plurality of connection links 150 are disposed parallel with each other so that the connection links 150 can be smoothly rotated, and uniformly distribute and support a load applied thereto.

As shown in FIG. 5, the linkage device 100 is configured such that the drive link 130, the driven link 190, the connection link 150 and the support link 170 are unfolded to form a triangular shape when the spoiler 200 is completely moved downward.

As such, if the spoiler 200 is completely moved downward, the drive link 130 and the driven link 190 are unfolded in an approximately linear shape, and the connection link 150 and the support link 170 form a predetermined angle therebetween and have a triangular shape, whereby the linkage device 100 can stably support the spoiler 200 against a load applied to the spoiler 200 when the vehicle travels. For this, the drive link 130, the driven link 190, the connection link 150 and the support link 170 may have different lengths.

As shown in FIGS. 1 to 3, the first drive device 300 may include: the first motor 320 which is installed on a back beam bracket 15 fixed on the bumper back beam 10 so as to transmit rotating force; and the first rotating shaft 340 which extends in opposite directions from the first motor 320 and is penetrated into the fixing bracket 110 and connected to the drive link 130.

That is, the first motor 320 is fixed in position because it is installed on the back beam bracket 15 fixed to the bumper back beam 10. The first rotating shaft 340 extending in the opposite directions from the first motor 320 is penetrated and connected to the fixing bracket 110 of the linkage device loft In this regard, the first rotating shaft 340 is rotatably connected to the fixing bracket 110, and the drive link 130 is connected to the first rotating shaft 340 on the fixing bracket 110, whereby the drive link 130 and the first rotating shaft 340 rotate together.

Preferably, the first motor 320 is provided with a gear set having a predetermined reduction ratio, so that the predetermined reduction ratio is applied between the first motor 320 and the spoiler 200 by the gear set, whereby the spoiler 200 can be reliably maintained at a predetermined position in a housed or extracted state. In addition, when the spoiler 200 is in the extracted state, even if the rotating force of the first motor 320 is not transmitted to the spoiler 200, the gear set may support the spoiler 200 against a load of air regardless of the angle at which the extracted spoiler 200 is oriented.

As shown in FIGS. 2 and 3, the second rotating shaft 400 is rotatably coupled to the first end of the support link 170. The second drive device 500 includes an up-down movable member 540 to which the second rotating shaft 400 is penetrated and connected so as to be rotatable. The up-down movable member 540 is connected with the length-variable unit 520 coupled to the spoiler 200.

In detail, the support link 170 is connected with the drive link 130, the driven link 190 and the connection link 150 so that the support link 170 can be moved upward or downward along with the spoiler 200 by the operation of the first drive device 300. Because the second rotating shaft 400 is coupled to the support link 170, the second rotating shaft 400 is moved upward or downward along with the spoiler 200 when the support link 170 is moved upward or downward.

The up-down movable member 540 of the second drive device 500 is rotatably coupled to the second rotating shaft 400. Thus, when the first drive device 300 is operated, the up-down movable member 540 is moved upward or downward along with the second rotating shaft 400. As such, the up-down movable member 540 is rotatably coupled to the second rotating shaft 400, so that, in response to the rotation of the linkage device 100 when the spoiler 200 is moved upward or downward, the up-down movable member 540 is rotated along with the linkage device 100, whereby rotational clearance can be absorbed, and the spoiler 200 and the up-down movable member 540 can be smoothly moved upward or downward.

The length-variable unit 520 installed on the up-down movable member 540 includes: a rotating bracket 522 which is rotatably installed on the end of the spoiler 200; a second motor 524 which is installed on the up-down movable member 540 and transmits rotating force; and a connection shaft 526 which extends from the second motor 524 and is threadedly coupled to the rotating bracket 522 so that, when the second motor 524 is operated, the rotating bracket 522 is moved upward or downward by rotation of the connection shaft 526.

The connection shaft 526 may be rotatably coupled to a separate bracket fixed on the end of the spoiler 200. The second motor 524 may be formed of a reversible motor to transmit the rotating force. In particular, the connection shaft 526, which extends from the second motor 524 and is rotated by the rotating force transmitted from the second motor 524, may be formed of a lead screw. A tap hole may be formed in the rotating bracket 522 so that the connection shaft 526 is threadedly coupled with the rotating bracket 522. Thus, when the connection shaft 526 is rotated by the operation of the second motor 524, the rotating bracket 522 can move in the longitudinal direction of the connection shaft 526 along the thread of the connection shaft 526. Therefore, when the second motor 524 of the length-variable unit 520 is operated, the rotating bracket 522 is moved by the rotation of the connection shaft 526. Because the rotating bracket 522 is coupled with the end of the spoiler 200, the spoiler 200 can be tilted in a predetermined direction depending on the direction in which the rotating bracket 522 moves.

In accordance with an embodiment of the present invention, the bumper back beam 10 may be installed in the rear of the vehicle and thus applied to the rear bumper. When the spoiler 200 is moved downward, it is extracted forward in a diagonal direction so as to prevent the spoiler 200 from being excessively exposed from the rear bumper. The direction in which the spoiler 200 is extracted when moved downward may be determined depending on the connection structure of the linkage device 100.

Furthermore, the length-variable unit 520 of the first drive device 300 is coupled to the front end of the spoiler 200. Thus, as the front end of the spoiler 200 is moved upward or downward by variation in length of the length-variable unit 520, the spoiler 200 can be tilted in a direction.

In addition, the first drive device 300 is disposed ahead of the second drive device 500. Thus, when the first drive device 300 is operated, the second drive device 500 moves upward or downward along with the spoiler 200. The angle at which the spoiler 200 is tilted can be controlled by the operation of the second drive device 500.

The first motor 320 and the second motor 524 each may be controlled by a controller. Depending on the speed of the vehicle or whether the vehicle is turning, the first motor 320 and the second motor 524 are selectively operated so that the air current can be controlled corresponding to the driving conditions of the vehicle.

Hereinbelow, the operation of an embodiment of the present invention will be described.

In the state in which the spoiler 200 is housed, as shown in FIG. 4, the first motor 320 of the first drive device 300 is not operated, and the drive link 130 and the driven link 190 that are coupled with the first rotating shaft 340 are in the folded state, whereby the spoiler 200 is maintained in the state in which it is housed in the bumper cover 20.

In this state, if the first motor 320 is operated, as shown in FIG. 5, the drive link 130 is rotated interlocking with the first rotating shaft 340, whereby the driven link 190 is rotated. Thus, the support link 170 coupled with the driven link 190 is guided by the connection link 150 and rotated downward. Consequently, the spoiler 200 connected to the support link 170 is moved downward. Then, the second rotating shaft 400 coupled to the support link 170 is moved along with the support link 170, so that the second drive device 500 installed on the second rotating shaft 400 is moved downward along with the spoiler 200.

As shown in FIG. 6, after the spoiler 200 and the second drive device 500 have been moved downward, when the second motor 524 is operated, the connection shaft 526 is rotated, so that the rotating bracket 522 moves along the thread of the connection shaft 526. As a result, the spoiler 200 coupled to the rotating bracket 522 is tilted.

As having described, in a variable spoiler apparatus of a rear bumper for vehicles according to embodiments of the present invention, a spoiler is housed in a lower portion of the rear bumper and, as needed, is extracted downward from the rear bumper so as to control the air flow, thus making it possible to enhance the driving stability and aerodynamic performance of the vehicle.

Although an embodiment of the present invention has been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. 

What is claimed is:
 1. A variable spoiler apparatus of a rear bumper for a vehicle, the variable spoiler apparatus comprising: a linkage device configured to be installed on a bumper back beam and configured to vary in length in an up-down direction during a rotating operation; a spoiler coupled to the linkage device and configured to be moved in the up-down direction by the rotation operation of the linkage device; a first drive device configured to be installed on the bumper back beam, the first drive device comprising a first rotating shaft coupled to the linkage device to transmit a rotating force, the first drive device being configured such that, when the first drive device is operated, the linkage device is rotated by a rotation of the first rotating shaft so that the spoiler is moved in the up-down direction; a second rotating shaft rotatably coupled to the linkage device, wherein when the linkage device is rotated, the second rotating shaft is moved in the up-down direction along with the rotation of the linkage device; and a second drive device, to which the second rotating shaft is penetrated and connected, wherein when the linkage device is rotated, the second drive device is moved in the up-down direction, wherein the second drive device comprises a length-variable unit coupled to an end of the spoiler, and wherein when the second drive device is operated, the spoiler is tilted by a length variation operation of the length-variable unit.
 2. The variable spoiler apparatus according to claim 1, wherein the linkage device comprises: a fixing bracket configured to be fixed to the bumper back beam, and to which the first rotating shaft is penetrated and connected; a drive link including a first end that is installed on the fixing bracket and coupled with the first rotating shaft so that the drive link rotates along with the first rotating shaft; a support link including a first end rotatably coupled to the fixing bracket through a connection link, and a second end rotatably coupled to the spoiler; and a driven link including a first end rotatably coupled to the drive link, and a second end rotatably coupled to the second link of the support link.
 3. The variable spoiler apparatus according to claim 2, wherein the drive link and the driven link are configured such that, when the spoiler is completely moved downward, the drive link and the driven link that have been in a folded state are unfolded to have an approximately vertical orientation.
 4. The variable spoiler apparatus according to claim 2, wherein the driven link extends from the first end thereof to the second end in a curved shape.
 5. The variable spoiler apparatus according to claim 2, wherein the connection link is rotatably coupled at a first end thereof to the fixing bracket, and is rotatably coupled at a second end thereof to the first end of the support link, and the connection link comprises a plurality of connection links provided parallel with each other.
 6. The variable spoiler apparatus according to claim 2, wherein the linkage device is configured such that the drive link, the driven link, the connection link and the support link are unfolded to form a triangular shape when the spoiler is completely moved downward.
 7. The variable spoiler apparatus according to claim 2, wherein the first drive device comprises: a first motor installed on a back beam bracket configured to be fixed on the bumper back beam and configured to transmit rotating force; and a first rotating shaft extending in opposite directions from the first motor, and penetrated into the fixing bracket and connected to the drive link.
 8. The variable spoiler apparatus according to claim 2, wherein the second rotating shaft is rotatably coupled to the first end of the support link, and wherein the second drive device is provided with an up-down movable member to which the second rotating shaft is penetrated and rotatably coupled, the up-down movable member being coupled with the length-variable unit coupled to the spoiler.
 9. The variable spoiler apparatus according to claim 8, wherein the length-variable unit comprises: a rotating bracket rotatably installed on the end of the spoiler; a second motor installed on the up-down movable member and configured to transmit rotating force; and a connection shaft extending from the second motor and threadedly coupled to the rotating bracket so that, when the second motor is operated, the rotating bracket is moved in the up-down direction by rotation of the connection shaft.
 10. The variable spoiler apparatus according to claim 1, wherein the bumper back beam is configured to be installed in a rear of the vehicle, and when the spoiler is moved downward, the spoiler is extracted forward in a diagonal direction.
 11. The variable spoiler apparatus according to claim 1, wherein the length-variable unit of the first drive device is coupled to a front end of the spoiler.
 12. A vehicle with a variable rear spoiler apparatus, the variable rear spoiler comprising: a linkage device installed on a bumper back beam and configured to vary in length in a vertical direction during a rotating operation of the linkage device; a spoiler coupled to the linkage device and configured to be moved in the vertical direction by the rotation operation of the linkage device; a first drive device installed on the bumper back beam, the first drive device comprising a first rotating shaft coupled to the linkage device to transmit a rotating force, the first drive device being configured such that, when the first drive device is operated, the linkage device is rotated by a rotation of the first rotating shaft so that the spoiler is moved in the vertical direction; a second rotating shaft rotatably coupled to the linkage device, wherein when the linkage device is rotated, the second rotating shaft is moved in the vertical direction along with the rotation of the linkage device; and a second drive device, to which the second rotating shaft is penetrated and connected, wherein when the linkage device is rotated, the second drive device is moved in the vertical direction, wherein the second drive device comprising a length-variable unit coupled to an end of the spoiler, and wherein when the second drive device is operated, the spoiler is tilted by a length variation operation of the length-variable unit.
 13. The vehicle according to claim 12, wherein the linkage device comprises: a fixing bracket fixed to the bumper back beam, and to which the first rotating shaft is penetrated and connected; a drive link including a first end that is installed on the fixing bracket and coupled with the first rotating shaft so that the drive link rotates along with the first rotating shaft; a support link including a first end rotatably coupled to the fixing bracket through a connection link, and a second end rotatably coupled to the spoiler; and a driven link including a first end rotatably coupled to the drive link, and a second end rotatably coupled to the second link of the support link.
 14. The vehicle according to claim 13, wherein the drive link and the driven link are configured such that, when the spoiler is completely moved downward, the drive link and the driven link that have been in a folded state are unfolded to have an approximately vertical orientation.
 15. The vehicle according to claim 13, wherein the driven link extends from the first end thereof to the second end in a curved shape.
 16. The vehicle according to claim 13, wherein the connection link is rotatably coupled at a first end thereof to the fixing bracket, and is rotatably coupled at a second end thereof to the first end of the support link, and the connection link comprises a plurality of connection links provided parallel with each other.
 17. The vehicle according to claim 13, wherein the first drive device comprises: a first motor installed on a back beam bracket fixed on the bumper back beam and configured to transmit the rotating force; and a first rotating shaft extending in opposite directions from the first motor, and penetrated into the fixing bracket and connected to the drive link.
 18. The vehicle according to claim 13, wherein the second rotating shaft is rotatably coupled to the first end of the support link, and wherein the second drive device is provided with an vertical movable member to which the second rotating shaft is penetrated and rotatably coupled, the vertical movable member being coupled with the length-variable unit coupled to the spoiler.
 19. The vehicle according to claim 18, wherein the length-variable unit comprises: a rotating bracket rotatably installed on the end of the spoiler; a second motor installed on the vertical movable member and configured to transmit the rotating force; and a connection shaft extending from the second motor and threadedly coupled to the rotating bracket so that, when the second motor is operated, the rotating bracket is moved in the vertical direction by rotation of the connection shaft.
 20. A method of operating a variable rear spoiler apparatus of a rear bumper for a vehicle, the method comprising: transmitting a rotating force by rotating a first rotating shaft of a first drive device, the first drive device being installed on a bumper back beam; rotating a linkage device installed on a bumper back beam, the linkage device having a length varying in a vertical direction during the rotating of the linkage device, wherein the first rotating shaft is coupled to the linkage device; providing a spoiler coupled to the linkage device and moving the spoiler in the vertical direction by the rotating of the linkage device; providing a second rotating shaft rotatably coupled to the linkage device; moving the second rotating shaft in the vertical direction along with the rotation of the linkage device; and providing a second drive device to which the second rotating shaft is penetrated and connected, wherein the second drive device comprising a length-variable unit coupled to an end of the spoiler; moving, when the linkage device is rotated, the second drive device in the vertical direction; and tilting, when the second drive device is operated, the spoiler by a length variation operation of the length-variable unit. 